A sensitive and label-free impedimetric biosensor based on an adjunct probe

A highly sensitive and label-free impedimetric biosensor is achieved based on an adjunct probe attached nearby the capture probe. In this work, the adjunct probe was co-assembled on the surface of gold electrode with the capture probe hybridized with the reporter probe, and then 6-mercapto-1-hexanol was employed to block the nonspecific binding sites. When target DNA was added, the adjunct probe functioned as a fixer to immobilize the element of reporter probe displaced by the target DNA sequences and made the reporter probe approach the electrode surface, leading to effective inhibition of charge transfer. The increase in charge transfer resistance is related to the quantity of the target DNA in a wide range. The linear range for target DNA with specific sequences was from 0.1 nM to 0.5 μM with a good linearity (R = 0.9988) and a low detection limit of 6.3 pM. This impedimetric biosensor has the advantages of simplicity, sensitivity, good selectivity, and large dynamic range.     

基于G-四链体-血红素和链式放大反应的基因检测传感器的构建

该文以特殊设计的DNA序列为捕获探针,以G-四链体-血红素复合物作为信号分子,利用链式反应实现目标DNA的灵敏检测。在目标DNA存在时,捕获探针与目标DNA相互识别,同时目标DNA能与辅助探针发生连续的链式反应,从而在电极表面引入大量G-四链体结构。血红素存在下,G-四链体可与血红素结合形成具有很强电化学信号的G-四链体-血红素复合物。用差分脉冲伏安法(DPV)扫描得到的电化学信号与体系中的目标DNA浓度存在对应关系,从而实现对目标DNA的检测。在各组分浓度最适的情况下,电流响应值与目标DNA浓度在0.01～10 pmol/L内具有良好的线性关系,检出限可达8 fmol/L。该传感器灵敏度高、特异性好,具有良好的应用前景。     

A Sandwich‐Type Electrochemical Biosensor for Detection of BCR/ABL Fusion Gene Using Locked Nucleic Acids on Gold Electrode

In this study, a sandwich‐type electrochemical enzyme‐based LNA‐modified DNA biosensor was developed to detect relative gene in chronic Myelogenous Leukemia first. This biosensor is based on a ‘sandwich’ detection strategy, which involves a pair of probes (a capture probe immobilized at the electrode surface and a reporter probe labeled biotin as an affinity tag for avidin‐HRP) modified LNA. Since biotin can be connected with avidin‐HRP, this biosensor offers an enzymatically amplified electrochemical current signal for the detection of target DNA. This new pattern exhibits high sensitivity and selectivity, and this biosensor has been used for an assay of PCR real sample with satisfactory result.     

Target label-free, reagentless electrochemical DNA biosensor based on sub-optimum displacement

One of the most time consuming and complex steps in the detection of DNA target with a biosensor is the previous labeling of the target. In this paper, a novel target label-free, reagentless and easy to use DNA biosensor is reported. Electrochemical transduction (cyclic voltammetry, differential pulse voltammetry and impedance spectroscopy) and optical red out by surface plasmon resonance were chosen for the platform optimization. This target label-free DNA detection method is based on displacement of sub-optimum labeled oligonucleotide. This strategy requires the pre-hybridization of the capture probe immobilized on the electrode surface with a sub-optimum mutated oligonucleotide pre-labeled with an electrochemically active ferrocene moiety. Due to the higher affinity of the target that is fully complementary to the capture probe, the sub-optimum ferrocene-labeled sequence is displaced when the fully complementary target is introduced into the system. The decrease of the electrochemical signal from the ferrocene verifies the presence of the target, which is proportional to the target concentration. A variation of this strategy was employed to enhance the ferrocene signal. A diffusional mediator, ferrocyanide, was introduced in the system to help in this purpose. This platform attains a stable, specific and reproducible response (5-15%), with a detection limit in the range of microM. This electrochemical sensor is the first example of this kind of sensor to detect cystic fibrosis, however, this configuration could be generically applied to any application where the detection of a DNA target is involved.     

Electrochemical biosensor based on nanogold-modified poly-eriochrome black T film for BCR/ABL fusion gene assay by using hairpin LNA probe

A novel electrochemical biosensor is described for detection of breakpoint cluster region gene and a cellular abl (BCR/ABL) fusion gene in chronic myelogenous leukemia (CML) by using thiolated-hairpin locked nucleic acids (LNA) as the capture probe. The hairpin LNA probe was immobilized on the nanogold (NG)/poly-eriochrome black T (EBT) film-modified glassy carbon electrode (GCE). The immobilized LNA probe could selectively hybridize with its target DNA on LNA/NG/EBT/GCE surface. The immobilization and hybridization of the LNA probe were characterized with cyclic voltammetry and electrochemical impedance spectroscopy. The hybridization of the immobilized LNA probe with the target DNA was detected by differential pulse voltammetry with the electroactive methylene blue as an indicator. The results indicated this new method has excellent specificity for single-base mismatch and complementary after hybridization, and a high sensitivity. This novel electrochemical biosensor has been used for assay of PCR real sample with satisfactory result.     

Magneto-mechanical detection of nucleic acids and telomerase activity in cancer cells

The ultra-sensitive magneto-mechanical detection of DNA, single-base-mismatches in nucleic acids, and the assay of telomerase activity are accomplished by monitoring the magnetically induced deflection of a cantilever functionalized with magnetic beads associated with the biosensing interface. The analyzed M13phi DNA hybridized with the nucleic acid-functionalized magnetic beads is replicated in the presence of dNTPs that include biotin-labeled dUTP. The resulting beads are attached to an avidin-coated cantilever, and the modified cantilever is deflected by an external magnetic field. Similarly, telomerization of nucleic acid-modified magnetic beads in the presence of dNTPs, biotin-labeled dUTP, and telomerase from cancer cell extracts and the subsequent association of the magnetic beads to the cantilever surface results in the lever deflection by an external magnetic field. M13phi DNA is sensed with a sensitivity limit of 7.1 x 10(-20) M by the magneto-mechanical detection method.     

Rapid detection of Staphylococcus aureus via a sensitive DNA hybridization assay based on a long-lifetime luminescent europium marker

A two-probe tandem nucleic acid hybridization assay for detection of Staphylococcus aureus is presented. It is based on a europium(III) complex as a marker that has a long fluorescence lifetime, high quantum yield and can be easily conjugated to an oligonucleotide signaling probe. The amino-modified capture probe was associated with the signaling probe to form a two-probe tandem DNA pattern that is complementary to the target DNA. The method was optimized in terms of hybridization temperature, hybridization time and washing time. This resulted in good specificity and sensitivity when detecting such bacteria in food samples.

基于工具酶信号放大技术电化学发光法检测凝血酶

利用巯基乙胺将合成的金纳米粒子氨基化;基于纳米粒子负载羧基化的联吡啶钌和巯基DNA制得电化学发光信号探针;采用酶循环信号放大技术,获得大量含新增DNA的溶液来捕获信号探针;以金电极为载体,将巯基DNA自组装到电极表面,依次杂交互补DNA和信号探针,构建电化学发光生物传感器.在优化的条件下,此传感器对凝血酶具有良好的响应,在3.0× 10-13～6.0×10-11 mol/L范围内,凝血酶的浓度与发光强度呈良好的线性关系,检出限为1.8× 10-13 mol/L(3a).采用酶切循环放大技术制备的生物传感器具有灵敏度高,选择性和重现性良好等特点.     

DNA analysis by application of Pt nanoparticle electrochemical amplification with single label response

This study demonstrates a highly sensitive sensing scheme for the detection of low concentrations of DNA, in principle down to the single biomolecule level. The previously developed technique of electrochemical current amplification for detection of single nanoparticle (NP) collisions at an ultramicroelectrode (UME) has been employed to determine DNA. The Pt NP/Au UME/hydrazine oxidation reaction was employed, and individual NP collision events were monitored. The Pt NP was modified with a 20-base oligonucleotide with a C6 spacer thiol (detection probe), and the Au UME was modified with a 16-base oligonucleotide with a C6 spacer thiol (capture probe). The presence of a target oligonucleotide (31 base) that hybridized with both capture and detection probes brought a Pt NP on the electrode surface, where the resulting electrochemical oxidation of hydrazine resulted in a current response.     

Human Serum Albumin−Gold Nanoparticle Based Impedimetric Sensor for Sensitive Detection of miRNA-200c

Here, human serum albumin conjugated gold nanoparticles (HSA−AuNPs) were synthesized by a simple route to develop an impedimetric sensor for miRNA-200c detection based on a selective oligo-hybridization process without any labeling. The synthetic DNA capture probe for miRNA-200c was decorated onto the HSA−AuNPs modified pencil graphite electrodes. Impedimetric signals were monitored after the hybridization process between the DNA probe and target miRNA-200c. HSA−AuNPs adsorption time, incubation time of the capture probe and hybridization time-temperature were optimized. The proposed miRNA-200c biosensor demonstrated proper sensitivity and selectivity, low detection limit (1.13 fM), good reproducibility and simple direct detection of miRNA-200c in serum.     

DNA-arrays with electrical detection: a label-free low cost technology for routine use in life sciences and diagnostics

Fast and highly parallel DNA analysis are essential for improved biomedical research and development. Currently fluorescence-based methods are state of the art in DNA microarray analysis. The necessity to modify the target DNA with labels is costly, laborious and requires skilled personnel. Moreover, false positive calls from unspecific adsorption are possible and it is difficult to discriminate perfect matching target sequences from those with a single mismatch. In this paper a new and simple electrochemical approach for hybridisation detection without the need of labelling the target DNA is described. The EDDA (Electrically Detected Displacement Assay) method uses a solution of short redox-labelled signalling oligonucleotides (oligonucleotides carrying a covalently attached redox active compound like ferrocene) to characterize the hybridisation state of label-free capture probe DNA immobilised on gold electrodes. The number of capture probes associated with signalling oligonucleotides is determined by chronocoulometry. This technique allows to separate the electrochemical response of capture probe associated signal probes from the response of freely diffusing signalling probes. In the absence of the complementary target sequences the redox-labelled signalling probes at the surface give rise to an instantaneous increase of the detection signal, while freely diffusing signalling probes show a significantly delayed response. Hybridisation with targets complementary to the capture probe displace the loosely associated signalling probes thereby decreasing the instantaneous signal. Besides an introduction to the EDDA technology, data validating the method for biological material will be presented and an outlook to the detection of single nucleotide polymorphisms (SNPs) is given.     

Sensitive electrochemical monitoring of nucleic acids coupling DNA nanostructures with hybridization chain reaction

Methods based on metal nanotags have been developed for metallobioassay of nucleic acids, but most involve complicated labeling or stripping procedures and are unsuitable for routine use. Herein, we report the proof-of-concept of a novel and label-free metallobioassay for ultrasensitive electronic determination of human immunodeficiency virus (HIV)-related gene fragments at an ultralow concentration based on target-triggered long-range self-assembled DNA nanostructures and DNA-based hybridization chain reaction (HCR). The signal is amplified by silver nanotags on the DNA duplex. The assay mainly consists of capture probe, detection probe, and two different DNA hairpins. In the presence of target DNA, the capture probe immobilized on the sensor sandwiches target DNA with the 3′ end of detection probe. Another exposed part of detection probe at the 5′ end opens two alternating DNA hairpins in turn, and propagates a chain reaction of hybridization events to form a nicked double-helix. Finally, numerous silver nanotags are immobilized onto the long-range DNA nanostructures, each of which produces a strong electronic signal within the applied potentials. Under optimal conditions, the target-triggered long-range DNA nanostructures present good electrochemical behaviors for the detection of HIV DNA at a concentration as low as 0.5 fM. Importantly, the outstanding sensitivity can make this approach a promising scheme for development of next-generation DNA sensors without the need of enzyme labeling or fluorophore labeling.     

Ultrasensitive electrochemical supersandwich DNA biosensor using a glassy carbon electrode modified with gold particle-decorated sheets of graphene oxide

We describe a supersandwich type of electrochemical DNA biosensor based on the use of a glassy carbon electrode (GCE) modified with reduced graphene oxide (rGO) sheets that are decorated with gold nanoparticles (Au NPs). Thiolated capture DNA (probe DNA) was covalently linked to the Au NPs on the surface of the modified GCE via formation of Au-S bonds. In presence of target DNA, its 3′ terminus hybridizes with capture probe and the 5′ terminus hybridizes with signal probe labeled with Methylene Blue (MB). On increasing the concentration of target DNA, hybridization between signal probe and target DNA results in the formation of three different DNA sequences that form a supersandwich structure. The signal intensity of MB improves distinctly with increasing concentrations of target DNA in the sample solution. The assembling process on the surface of the electrode was studied by scanning electron microscopy (SEM) and electrochemical impedance spectroscopy (EIS). Differential pulse voltammetry (DPV) was used to monitor the hybridization event by measuring the changes in the peak current for MB. Under optimal conditions, the peak currents in DPV for MB linearly increase with the logarithm of target DNA concentration in the range from 0.1 μM to1.0 fM, with a detection limit of 0.35 fM (at an signal/noise ratio of 3). This biosensor exhibits good selectivity, even over single-base mismatched target DNA.

Detection of bar gene encoding phosphinothricin herbicide resistance in plants by electrochemical biosensor

An electrochemical biosensor for the detection of bar gene coding phosphinothricin herbicide resistance is presented. The detection was based on hybridization reaction between the specific to bar gene 19-mer probe immobilized on the electrode surface and complementary DNA in a sample. Single-stranded DNA probe specific to bar gene was covalently attached by 5'-phosphate end to the surface of carbon paste electrode. Outer layer of a conventional CPE was provided with carboxyl groups of stearic acid. ssDNA was coupled to the electrode through ethylenediamine with the use of water-soluble 1-ethyl-3(3'-dimethylaminopropyl)-carbodiimide and N-hydroxy-sulfosuccinimide as activating reagents. Hybridization reaction at the electrode surface was detected via Co(bpy)(3)(3+), which possess a much higher affinity to the resulting DNA duplex compared to ssDNA probe. Detection limit of the sensor was 0.1 microM of target DNA fragments and its response was linear from 5 to 20 microM. Hybridization event was also detected by measuring guanine peak but this approach presented distinctly higher detection limit (1 muM) and lower reproducibility. Complete time of one measurement with the use of the biosensor including covalent attachment of ethylenediamine (linker) and ssDNA probe to the electrode, hybridization with target and interaction with electroactive indicator was about 70 min.     

高灵敏纳米金比色芯片检测乙型肝炎病毒DNA及其变异

构建了新型纳米金比色芯片,利用Taq DNA连接酶的连接特异性,将其与乙型肝炎病毒DNA( HBV-DNA)靶序列完全互补杂交的捕获探针(固定在芯片上)和纳米金修饰的探针连接成一条链,从而将纳米金颗粒固定到芯片点阵上,再通过银染反应放大,形成裸眼可见的显色信息.通过点阵的位置及灰度,即可判断HBV-DNA靶序列的单碱基突变,并得出相对定量信息.本实验对不同浓度的HBV-DNA靶序列进行了检测.结果显示:此技术对单碱基突变有很强的特异性识别能力,并且具有较高的灵敏度(约10 pmol/L),在10～100 pmol/L浓度范围内表现出较好的线性关系.该技术检测时间短(＜1 h)、操作简单、不需要特殊的检测设备,具有很好的临床应用前景.     

The application of β-cyclodextrin derivative functionalized aligned carbon nanotubes for electrochemically DNA sensing via host-guest recognition

We functionalized aligned carbon nanotubes (ACNTs) electrode with a new kind of β-cyclodextrin (β-CD) derivative through diazotization reaction. The resulting β-CD/ACNTs electrode was used to detect DNA hybridization in homogeneous solution based on host–guest recognition technology. In the sensing protocol, one special DNA probe was designed with a stem-loop structure and both ends modified, which we called dually labeled DNA probe (DLP). One end of the DLP was labeled with dabcyl as guest molecule for β-CD/ACNTs electrode capture, and the other end was labeled with a CdS nanoparticle as an electrochemical tag to indicate the occurrence of DNA hybridization. In the absence of the target DNA sequence, the DLP maintains its hairpin structure in solution phase and would not be captured and detected by the β-CD/ACNTs electrode. In the presence of the complementary target sequence, the conformational structure of the DLP was altered and a double-stranded DNA (dsDNA) molecule was formed by the hybridization of DLP and complementary DNA sequence. Consequently, the dsDNA was captured by the β-CD/ACNTs electrode owing to guest–host recognition between β-CD and dabcyl. The electrochemical signal from the CdS nanoparticle–dsDNA/β-CD/ACNTs was then measured. Under optimized detection conditions, the proposed method showed high sensitivity and selectivity with a detection limit of 5.0 × 10⁻¹³ M for complementary DNA sequence.     

Chemiluminescent detection of DNA hybridization and single-nucleotide polymorphisms on a solid surface using target-primed rolling circle amplification

A new chemiluminescent (CL) method has been developed for the sensitive detection of DNA hybridization and single-nucleotide polymorphisms (SNPs) with target-primed rolling circle amplification (RCA). The capture oligonucleotide probe is firstly immobilized on a polystyrene well plate and then hybridized with the wild DNA target. A designed padlock probe is circularized after perfect hybridization to the DNA target. Then the RCA reaction can be initiated from the DNA target that acts as a primer and generates a long tandem single-strand of DNA with repeat sequences. In contrast, the mutant DNA target, which contains a mismatched base with the padlock probe, cannot initiate the RCA reaction and primes only a limited extension with the unligated padlock probe. Afterwards, a biotinylated oligonucleotide is used to hybridize with the RCA product in each repeat sequence and streptavidin-alkaline phosphatase (STV-AP) is employed to combine the anchored biotin. The DNA target is detected with the CL reaction of STV-AP and 3-(2'-spiroadamantane)-4-methoxy-4-(3'-phosphoryloxy)phenyl-1,2-dioxetane (AMPPD). With the RCA-based method, the sensitivity of DNA detection can be increased by about two orders of magnitude compared with that of direct DNA hybridization. A DNA target as low as 3.6 pM can be detected. Wild-type DNA and the one-base mutant DNA can be differentiated with high selectivity through this RCA reaction.     

An electrochemical DNA sensor based on a layers-film construction modified electrode

This work developed a relatively inexpensive and layers-film construction electrochemical sensor for DNA recognition and its performance was investigated. The Fe(3)O(4) magnetic nanoparticles-cysteine were immobilized on the carbon paste electrode (CPE) surface using magnetic force. Multiwalled carbon nanotubes (MWCNTs), gold nanoparticles (GNPs), and chitosan (Chi) were used successively to coat on the electrode surface. The thiolated capture probe was assembled and competitively hybridized with the target nucleic acid and biotinylated response probe. The electrochemical behavior was analyzed by cyclic voltammetry and electrochemical impedance spectroscopy. In addition, the sensor performance was also analyzed by introducing the notion of detection efficiency. The experimental results showed that although the electron transfer capability of the CPE is less strong than that of a metal electrode used in the DNA sensor, the materials modified on the CPE could significantly improve the performance. A detection limit of 1 nM of target DNA and a sensitivity of 2.707 × 10(3) mA M(-1) cm(-2) were obtained. Although the resulting detection limit was not remarkable, further experiments could improve it.     

Mechano-transduction of DNA hybridization and dopamine oxidation through electrodeposited chitosan network

While microcantilevers offer exciting opportunities for mechano-detection, they often suffer from limitations in either sensitivity or selectivity. To address these limitations, we electrodeposited a chitosan film onto a cantilever surface and mechano-transduced detection events through the chitosan network. Our first demonstration was the detection of nucleic acid hybridization. In this instance, we electrodeposited the chitosan film onto the cantilever, biofunctionalized the film with oligonucleotide probe, and detected target DNA hybridization by cantilever bending in solution (static mode) or resonant frequency shifts in air (dynamic mode). In both detection modes, we observed a two-order of magnitude increase in sensitivity compared to values reported in literature for DNA immobilized on self-assembled monolayers. In our second demonstration, we coupled electrochemical and mechanical modes to selectively detect the neurotransmitter dopamine. A chitosan-coated cantilever was biased to electrochemically oxidize dopamine solution. Dopamine's oxidation products react with the chitosan film and create a tensile stress of approximately 1.7 MPa, causing substantial cantilever bending. A control experiment was performed with ascorbic acid solution. It was shown that the electrochemical oxidation of ascorbic acid does not lead to reactions with chitosan and does not change cantilever bending. These results suggest that chitosan can confer increased sensitivity and selectivity to microcantilever sensors.     

Detection of trace organophosphorus vapor with a self-assembled bilayer functionalized SiO2 microcantilever piezoresistive sensor

Using piezoresistive SiO₂ microcantilever technology, we present an ultra-sensitive chemical sensor for trace organophosphorus vapor detection. A self-assembled composite layer of Cu²⁺/11-mercaptoundecanoic acid is modified on the surface of the sensing cantilever as a specific coating to capture PO containing compounds. Experimental results indicate that the sensor can be quite sensitive to DMMP vapor (well known as a simulant of nerve agent). The signal-noise-limited detection resolution of the sensor is experimentally obtained as low as several parts per billion. Besides that the sensor can yield reversible and repeatable response to DMMP vapor, adsorption of DMMP on the self-assembled composite layer is well fit to the Langmuir isotherm model.